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Berry et al.
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MALDI Imaging Mass Spectrometry of Phospholipids in the Mouse
Lung
Karin A. Zemski Berry1, Bilan Li2, Susan D. Reynolds2, Robert M. Barkley1, Miguel A.
Gijón1, Joseph A. Hankin1, Peter M. Henson2, and Robert C. Murphy1
1 Department of Pharmacology, University of Colorado Denver, 12801 E. 17th Ave., Mail
Stop 8303, Aurora, CO 80045
2 Department of Pediatrics, National Jewish Health, 1400 Jackson Street, Denver, CO
80206
Correspondence to: Robert C. Murphy, Ph.D.
Department of Pharmacology, MSC 8303
University of Colorado Denver
RC1 South, rm. L18-6120
12801 E. 17th Ave., Aurora, CO 80045
Tel: (303) 724-3352, Fax: (303) 724-3357
E-mail: [email protected]
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List of Abbreviations PUFA – polyunsaturated fatty acid MALDI – matrix-assisted laser desorption/ionization IMS – imaging mass spectrometry LC/MS/MS – liquid chromatography/mass spectrometry/mass spectrometry FFPE – formalin fixed paraffin embedded OCT – optimal cutting temperature compound PVA – polyvinyl alcohol DHAP – 2,6-dihydroxyacetophenone DHB – 2,5-dihydroxybenzoic acid PPG – polypropylene glycol mOCT – modified OCT DAPI - 4',6-diamidino-2-phenylindole ESI – electrospray ionization PC – phosphatidylcholine PE – phosphatidylethanolamine PG - phosphatidylglycerol PI - phosphatidylinositol PS - phosphatidylserine DPPC – dipalmitoyl-PC PMPC - palmitoyl-myristoyl-PC PPoPC - palmitoyl-palmitoleoyl-PC POPC - palmitoyl-oleoyl-PC PAPC - palmitoyl-arachidonoyl-PC PDoPC- palmitoyl-docosahexaenoyl-PC SAPC - stearoyl-arachidonoyl-PC SM(d18:1/16:0)+Na - sodiated N-(hexadecanoyl)-sphingenine-phosphocholine POPG - palmitoyl-oleoyl-PG SOPS - stearoyl-oleoyl-PS SAPE - stearoyl-arachidonoyl-PE SAPI - stearoyl-arachidonoyl-PI PLPG - palmitoyl-linoleoyl-PG SAPS - stearoyl-arachidonoyl-PS HAPE - 1-O-hexadecenyl-arachidonoyl-PE PAPI - palmitoyl-arachidonoyl-PI PPoPG - palmitoyl-palmitoleoyl-PG
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Lipid mediators are important in lung biochemistry and are derived from the
enzymatic oxidation of arachidonic and docosahexaenoic acids, which are
polyunsaturated fatty acids (PUFA) that are present in phospholipids in cell membranes.
In this study, matrix-assisted laser desorption/ionization (MALDI) imaging mass
spectrometry (IMS) was used to determine the localization of arachidonate- and
docosahexaenoate-containing phospholipids in mouse lung. These PUFA-containing
phospholipids were determined to be uniquely abundant at the lining of small and large
airways, which were unequivocally identified by immunohistochemistry. In addition, it
was found that the blood vessels present in the lung were characterized by sphingomyelin
molecular species and lung surfactant phospholipids appeared evenly distributed
throughout the lung parenchyma, indicating alveolar localization. This technique
revealed unexpected high concentrations of arachidonate- and docosahexaenoate-
containing phospholipids lining the airways in pulmonary tissue, which could serve as
precursors of lipid mediators affecting airways biology.
Supplementary key words: arachidonic acid, lipid localization, cryoembedding agent,
lipid mediators, pulmonary tissue
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Introduction
Lipids play very important roles in lung biology as signaling molecules for
inflammation (1), antiviral protectants (2), and as a structural component to prevent
alveolar collapse (3). Leukotrienes and prostaglandins are lipid mediators that are
involved in lung inflammation and are responsible for impairment of mucociliary
clearance of particles, promotion of bronchoconstriction and mucous secretion,
chemotactic recruitment of neutrophils to the airways, and facilitation of pulmonary
edema (4,5). In fact, drugs that are receptor antagonists of cysteinyl-leukotrienes or
interfere with cysteinyl-leukotriene production are frequently used in treating asthma (6).
These lipid mediators are derived from the enzymatic hydrolysis of arachidonate-
containing phospholipids, likely a phospholipase A2, and subsequent metabolism of free
arachidonic acid to the oxygenated lipid mediator. Metabolites of docosahexaenoic acid
are also emerging as important mediators of inflammation resolution in the lung (7) and
likewise the docosahexaenoate is stored in membrane phospholipids that must be
hydrolyzed to generate free docosahexaenoic acid. Since these mediators act in an
autocrine and paracrine manner, the specific localization of arachidonate- and
docosahexaenoate-containing phospholipid precursors plays a critical role in the driving
the production of docosanoids, leukotrienes, and prostaglandins at local sites in the lung.
Chemical imaging techniques, such as immunohistochemistry and dye staining,
are typically used to enable the detection and determine the localization of biological
compounds. However, the ability to image the location of specific lipids in tissues has
been limited. Staining with Nile Red (10), Oil Red O (11), or BODIPY 493/503 (12)
provides the localization of only the neutral lipids in a tissue. Antibodies for different
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phospholipid headgroups are available to study their localization in tissues by
immunohistochemical methods (13), but specific antibodies for a particular lipid
molecular species of interest are not readily available. Neither of these methods provides
spatial distribution information for specific lipid molecular species in a tissue, and
consequently there is a need for an effective method that indicates the localization and
acyl chain composition of lipids in tissue. Localization of lipid molecular species in some
tissues has been examined by microdissection of specific anatomical features followed by
solvent extraction and LC/MS or LC/MS/MS analysis (14), however the non-rigid nature
of the lung, with interlaced architecture of airways and blood vessels of varying size and
shape, make this organ poorly suited for this approach.
Matrix-assisted laser desorption/ionization (MALDI) imaging mass spectrometry
(IMS) has been developed as a powerful method for investigating the distribution of
biomolecules within tissues (15). Analyte ions are produced directly from a tissue slice
coated with MALDI matrix and sequential mass spectra are acquired by rastering the
laser beam across the tissue surface. This method is unique compared to other imaging
methods because the distribution as well as the composition of many compounds of
interest can be determined in a single experiment. Images can be obtained by plotting the
intensity of the analytes of interest as a function of the x-y coordinates. While much
research in MALDI IMS has focused on the spatial distribution of proteins and peptides
(15), the majority of ion current generated by MALDI IMS is related to desorption of
phospholipids from the tissue (16). Recent studies have also revealed that the abundance
of the phosphatidylcholine (PC) related ions in MALDI IMS images is remarkably
correlated with local concentrations of that PC lipid in tissue regions (17). Thus MALDI
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IMS offers unique information about the molecular species present on a tissue without
the need for specific probes or staining.
In order to preserve the normal lung architecture, most histological preparation
methods require both inflation and embedding of the lung (18). In this study, it was
determined that the traditional methods of lung histological preparations, agarose
inflation with either formalin fixation paraffin embedding (FFPE) or optimal cutting
temperature compound (OCT) embedding, were incompatible with MALDI IMS of
phospholipids and therefore a new inflation and embedding agent was developed that was
MALDI IMS compatible. Using MALDI IMS, phospholipid molecular species that
contained either esterified arachidonic or docosahexaenoic acid were localized to specific
anatomical regions of the lung.
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Methods
Reagents - Low melting point agarose was obtained from Promega (Madison,
WI). Polyvinyl alcohol (PVA) 6-98, 2,5-dihydroxybenzoic acid (DHB), 2,6-
dihydroxyacetophenone (DHAP), and sodium azide were purchased from Sigma Aldrich
Chemical Company (St. Louis, MO). Optimal cutting temperature compound (OCT) was
obtained from Ted Pella, Inc (Redding, CA). Hanks’ balanced salt solution (1X) (HBSS)
was purchased from Invitrogen (Carlsbad, CA). Polypropylene glycol, average MW
2000 g/mol (PPG 2000), and organic solvents were purchased from Fisher Scientific
(Fair Lawn, NJ).
Animals - C57BL6 mice were from The Jackson Laboratory (Bar Harbor, ME).
The Institutional Animal Care and Use Committee at the University of Colorado Denver
approved all animal experiments.
Preparation of modified OCT compound (mOCT) - A 10% PVA 6-98 solution
was made by the addition of PVA 6-98 (10 g) to HBSS (100 ml). The solution was
microwaved and then shaken for 16 cycles of 30 s each in order to dissolve the PVA 6-
98. This 10% PVA 6-98 solution was allowed to cool to room temperature, then PPG
2000 (8 ml) and sodium azide (100 mg) were added to make the final mOCT: 10% (w/v)
PVA 6-98, 8% (v/v) PPG 2000, 0.1% (w/v) NaN3.
Lung inflation and slicing – A solution of 1% low melting point agarose was
prepared in HBSS by heating in a microwave oven. It was then cooled to 42°C and kept
at that temperature until inflation. Following euthanasia of the mice by CO2
asphyxiation, lungs were deflated by puncture of the diaphragm and the front rib cage
was removed. The trachea was cannulated using a catheter (18G Safelet Cath, Exelint
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International, Los Angeles, CA) and lungs were inflated with mOCT or agarose at 20 cm
water pressure. The left lung was excised from the mouse, rinsed with HBSS, blotted
dry, placed in a disposable cryomold embedded with OCT or mOCT and then placed in a
-20°C freezer. The embedded lung was mounted onto a cutting chock with OCT and
sliced at a thickness of 12 µm with a cryostat (Reichert-Jung Cryocut 1800) at -20°C.
The lung sections were placed onto glass coverslips and stored for no longer than one
week at -20°C until matrix application and MALDI imaging. Additionally, another
agarose inflated left lobe was formalin-fixed, paraffin-embedded (FFPE) using standard
procedures. The FFPE left lobe was sliced at a thickness of 4 µm with a microtome and
placed onto glass coverslips. The coverslips were dipped into xylene (2x) to remove the
paraffin before matrix application. Two slices of a FFPE lung from one mouse, 5 slices
of an OCT embedded lung from one mouse and at least 15 different slices of a mOCT
inflated and embedded lung from 3 different mice were analyzed by MALDI IMS. For
the immunofluorescence experiments described below, adjacent sections were collected
onto Superfrost slides.
Matrix application - The glass coverslips containing the lung sections were
attached to a stainless steel MALDI plate using copper tape and the DHB matrix was
deposited by sublimation (19). The MALDI plate was attached to the condenser using
double-sided thermally conductive tape (3M, St. Paul, MN). The conditions during
sublimation of DHB matrix were a pressure of 0.05 Torr, condenser temperature of 15°C
(42 V applied to a heating mantle), and 275 mg DHB in the sublimator. The heat was
applied for 11 min, which resulted in the deposition of a thin layer of DHB matrix. For
negative ion MALDI imaging DHAP was used as the matrix and the conditions of
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sublimation were a pressure of 0.05 Torr, condenser temperature of 13°C (36 V applied
to a heating mantle), and 150 mg DHAP in the sublimator. The heat was applied for 13
min, which resulted in the deposition of a thin layer of DHAP matrix. After MALDI
imaging was completed, the glass coverslip containing the lung section was carefully
removed from the MALDI plate and dipped in methanol to remove the matrix and fix the
tissue prior to modified Giemsa staining, which was performed using standard protocols.
MALDI IMS - A quadrupole-TOF tandem mass spectrometer with an orthogonal
MALDI source (QSTAR XL, Applied Biosystems/MDS Sciex, Thornhill, Ontario,
Canada) was used to acquire images. MALDI mass spectra were obtained using a
nitrogen laser (337 nm) at a power of 100 µJ and a pulse rate of 20 Hz with an
accumulation time of 243 ms per image spot. The MALDI plate was moved at a rate of
12.75 mm/min and after each horizontal line was completed the plate was moved
vertically 50 µm. The mass spectrometric data were processed using a specialized script
for Analyst software (Applied Biosystems/MDS Sciex, Thornhill, Ontario, Canada) at a
mass resolution of 0.1 amu and images were visualized using TissueView software
(Applied Biosystems/MDS Sciex). The lateral resolution of this MALDI IMS technique
is approximately 50 µm. Collisional activation of selected ions was carried out using
relative collision energy of 40 V with argon as collision gas.
Lung homogenization, lipid extraction, and electrospray ionization mass
spectrometry (ESI-MS) - The mouse left lung was homogenized in 1:1 methanol/HBSS (1
ml) and the phospholipids were then extracted according to the method of Bligh and Dyer
(20). The extracted phospholipids from lung homogenate were resuspended in 60:20:20
(v:v:v) methanol/acetonitrile/water with 1 mM ammonium acetate for positive and
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negative ion mass spectrometric analysis. Additionally, the PC lipids were separated by
normal phase HPLC from the other phospholipid classes (21) and resuspended in
60:20:20 (v:v:v) methanol/acetonitrile/water and infused into a Sciex API QTRAP mass
spectrometer (PE Sciex, Toronto, Canada) at a flow rate of 5 µl/min. In the negative ion
mode, the experimental parameters used to obtain the product ion spectra were an
electrospray voltage of -4500 V, a declustering potential of -50 V, and a collision energy
of -50 V.
Immunofluorescence - Adjacent sections to those analyzed by MALDI were used
for dual immunofluorescence staining to aid in differentiation of airways from blood
vessels in lung slices. Sections were placed at room temperature (RT) overnight, fixed in
10% neutral buffered formalin for 1 h at RT, and washed in deionized water. Antigens
were retrieved by the microwave method (15 min, 1200 W) in 0.01 mM citrate buffer
(pH 6.0). Slides were cooled to room temperature, washed with deionized water and
equilibrated in phosphate buffered saline for 5 min. Sections were blocked in blocking
buffer (5% fetal bovine serum in phosphate buffered saline) for at least 1 h. Primary and
secondary antibodies were diluted in blocking buffer. Antigens were detected with mouse
IgG2b anti-acetylated tubulin (Sigma, 1:8000) and goat IgG anti thrombomodulin
(CD141, R&D systems, 1:300), overnight at 4°C. Sections were washed with deionized
water and equilibrated in 1X PBS for 10 min. Antigen-antibody complexes were detected
with 1:500 (in blocking buffer) dilutions of secondary antibodies: Alexa 488-conjugated
donkey anti-mouse IgG2b and Alexa 594-conjugated donkey anti-goat IgG (Invitrogen).
Slides were counterstained with 1 µg/ml 4',6-diamidino-2-phenylindole (DAPI). Images
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were acquired using a Zeiss Imager.Z1 fluorescent microscope (Zeiss) equipped with an
Axiocam HRc black and white digital camera.
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Results
Inflation and embedding of lungs. The positive ion ESI mass spectrum of lipids
solvent extracted from a mouse lung homogenate (Figure 1A), indicated numerous PC
molecular species present in this tissue as [M+H]+ observed between m/z 700-850. This
population of PC molecular species was used to evaluate the initial attempts to image
phospholipids in the mouse lung. Lung samples obtained for histological studies typically
are inflated using low melting agarose and either fixed with formalin and embedded in
paraffin or embedded with OCT and frozen. The total positive ions obtained as a result
of MALDI imaging of a FFPE lung resulted in the absence of phospholipid ion signal
(Figure 1B). For example ions at m/z 734.6 or 810.6 present as abundant [M+H]+ in the
lung homogenate (Figure 1A) were not abundant ions generated during MALDI imaging
of the FFPE lung and furthermore did not reveal lung anatomical structure when rendered
into images (Supplementary Figures 1A-C). The next attempt at MALDI imaging of lung
phospholipids was with an agarose inflated, OCT embedded lung. The positive ion
MALDI mass spectrum of this preparation (Figure 1C) indicated the presence of some
phospholipids with low signal intensity, including a few of the major ions, such as m/z
734.6, present in the ESI mass spectrum of lung homogenate (Figure 1A). The MALDI
images obtained of phospholipids in the agarose inflated, OCT embedded lung were
unimpressive, though some definition of the larger airways was observed (Supplementary
Figures 1D-F).
OCT contains a benzalkonium salt as a preservative, which can suppress the
ionization of analytes during the MALDI process (22), and adducts of benzalkonium with
endogenous phosphatidylcholine lipids have also been observed as ions in MALDI mass
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spectra (data not shown). Therefore, a new embedding agent was developed that
supported the lung tissue while cutting on a cryostat and caused minimal interference in
the MALDI mass spectrum in the phospholipid mass region (m/z 700-900). The final
modified OCT (mOCT) composition was 10% polyvinylalcohol (PVA) 6-98 and 8%
polypropylene glycol (PPG) 2000, which was based on the OCT composition and a
previous study on the formulation of cryoembedding media (23). The positive ion
MALDI mass spectrum of a mOCT inflated and embedded lung directly from the tissue
(Figure 1D) indicated the presence of numerous phospholipid molecular species, such as
m/z 706.6, 734.6, 760.6, 782.6 and 810.6, which were also present in the positive ion ESI
mass spectrum of lung homogenate (Figure 1A). Additionally, the MALDI mass
spectrum of a lung slice (Figure 1D) revealed an abundant ion at m/z 756.6 not present in
the ESI mass spectrum of the extracted lung lipids. Most likely this ion corresponded to
a sodiated PC species of m/z 734.6 by the addition of 22 Daltons to the [M+H]+ species.
While the ESI mass spectrum of lung homogenate (Figure 1A) was obtained by
controlling the ionic composition of the electrospray solvent, the MALDI ions would be
subject to local concentrations of alkali metal ions in the tissue that can generate
abundant Na+ in the MALDI plume and adduct this desorbed phosphatidylcholine. In
addition, the pulmonary morphology of the lung slices was preserved using mOCT when
the stained slices were examined microscopically (see below). In general the quality of
the MALDI images obtained using mOCT were superior when compared to the MALDI
images from FFPE and OCT embedded lungs.
Positive Ion MALDI Images. From the mass spectra obtained from each pixel
across the lung tissue, an ion of interest can be extracted and an image of that particular
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ion distribution in the tissue can be visualized. The extracted ion MALDI image of the
most abundant MALDI ion, m/z 734.6 (Figure 2A) and its sodiated adduct at m/z 756.6
(data not shown), indicated a relatively uniform intensity in the lung parenchyma as well
as the positions of void regions where airways and vessels occurred when compared to
the modified Giemsa stain (Figure 2F) of this same tissue slice post-MALDI IMS. The
positive ion collision induced dissociation (CID) mass spectra from the tissue-derived
MALDI ion (Supplementary Figure 2A) and the negative ion electrospray CID of the
corresponding [M-CH3]- ion (Supplementary Figure 3A) were consistent with the
identification of m/z 734.6 as dipalmitoyl-PC (DPPC) (24,25). Collisional activation of
m/z 756.6 yielded products ions at m/z 697.6 (loss of trimethylamine) and m/z 147
(sodiated cyclic 1,2-phosphodiester) characteristic of sodiated adducts of
phosphatidylcholines (26) (data not shown). In addition, the positive ion MALDI images
of m/z 706.6, palmitoyl-myristoyl-PC (PMPC), (Supplementary Figure 4A) and m/z
732.6, palmitoyl-palmitoleoyl-PC (PPoPC), (Supplementary Figure 4B) had a
distribution very similar to DPPC.
The MALDI image of m/z 760.6 (Figure 2B) revealed a relatively uniform
intensity across the lung parenchyma, but a slightly higher intensity along the edges of
anatomical structures that appeared to be airways. The ion at m/z 760.6 was identified as
palmitoyl-oleoyl-PC (POPC) from positive ion CID of the ion directly from the tissue
(Supplementary Figure 2B) and the corresponding negative ion electrospray CID data
(Supplementary Figure 3B).
In sharp contrast, the MALDI images of m/z 782.6 (Figure 2C) and m/z 806.6
(Figure 2D) indicated that these phospholipid molecular ions were highly abundant along
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the edge of the putative airways observed in the modified Giemsa stain (Figure 2F) and
were also present in the alveolar region, albeit with lower abundance. The positive ion
CID data of these ions directly from the tissue on the MALDI plate (Supplementary
Figure 2C-D) and the negative ion electrospray CID of the corresponding [M-CH3]- ions
(Supplementary Figure 3C-D) were consistent with the identification of m/z 782.6 and
806.6 as palmitoyl-arachidonoyl-PC (PAPC) and palmitoyl-docosahexaenoyl-PC
(PDoPC), respectively (24,25). A similar MALDI image indicating a unique location at
the edge of airways was observed in positive ion mode for m/z 810.6 PC (stearoyl-
arachidonoyl-PC, SAPC) (Supplementary Figure 4C). Additionally, the positive ion CID
spectra of m/z 782.6, 806.6, and 810.6 indicated that these ions were derived from a
mixture of molecular species due to the appearance of an ion corresponding to a loss of
trimethylamine and a sodiated cyclic 1,2-phosphodiester ion (26) and were most likely
composed of the sodium adduct of POPC, oleoyl-linoleoyl-PC, and stearoyl-oleoyl-PC,
respectively. However, due to the low abundance of these characteristic sodiated PC ions
in the positive ion CID spectra, it was determined that these sodiated adducts were not the
major PC species making up the ion abundance at each mass-to-charge ratio.
In addition to airways, blood vessels are also abundant anatomical features in lung
tissue. This was readily observed in the modified Giemsa stain (Figure 2F) in which
most of the blood vessels were still filled with blood since no perfusion was performed
and the tissue was not rinsed. Many of the phospholipids observed in the positive ion
MALDI images of the lung did not highlight the blood vessels (Figures 2A-D).
However, the MALDI image of the ion at m/z 725.6 indicated the enrichment of this
molecular species at the edges of the pulmonary blood vessels (Figure 2E). The positive
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ion CID spectrum for this ion directly from the tissue on the MALDI plate
(Supplementary Figure 2E) was consistent with the identification of m/z 725.6 as
sodiated N-(hexadecanoyl)-sphingenine-phosphocholine (SM(d18:1/16:0)+Na)).
Immunohistochemistry. The blood vessels and airways in the lung were
unequivocally identified by dual immunofluorescence on a lung section adjacent to that
used for the MALDI imaging experiment. The modified Giemsa stain (Figure 3A), along
with the MALDI ion images of PAPC, m/z 782.6 (Figure 3B), and SM(d18:1/16:0)+Na,
m/z 725.6 (Figure 3C), were magnified at the boxed in region of the lung tissue in Figure
2F. From these two separate positive ion MALDI images (Figures 3B and 3C), it
appeared that PAPC and SM(d18:1/16:0)+Na were not co-localized and when the
positive ion MALDI images were merged (Figure 3D), there was a clear difference in the
localization of PAPC (green) and SM(d18:1/16:0)+Na (red).
The adjacent lung section was stained to visualize acetylated tubulin (green),
specific for airway ciliated cells, and thrombomodulin (red), specific for blood vessels.
In addition, DAPI (4',6-diamidino-2-phenylindole) was used to visualize cell nuclei. The
DAPI counterstain of this lung section illustrated the lacy appearance of the alveolar
region, as well as the characteristic nuclear shape and density of blood vessel and major
airway cells (Figure 3E). Higher magnifications of the immunofluorescence images
aided in the identification of two major airways and one large blood vessel (Figures 3F-
H). Additionally, capillaries present in the alveolar region were visualized with the
thrombomodulin stain. MALDI IMS and immunofluorescence staining were also
performed on adjacent lung sections that contained a main axial airway and a small blood
vessel (Supplementary Figure 5). From these combined data, it was concluded that both
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small and major airways had PUFA-containing phospholipids and that both small and
large blood vessels contained SM(d18:1/16:0)+Na.
Negative Ion MALDI Images. The phospholipid molecular species observed as
abundant [M-H]- in the negative ion ESI mass spectrum of solvent extracted lipids from
the lung homogenate (Figure 4A) were quite similar to the molecular species present in
the negative ion MALDI mass spectrum of the entire left lung directly from the lung
tissue (Figure 4B). The identity of the phospholipids that generated these negative ions
was deduced from collisional activation of each abundant [M-H]- ion in the ESI data
(Figure 4A) as well as the same ion observed in the MALDI IMS (Figure 4B). For
example the negative ion MALDI CID spectra obtained directly from the tissue
(Supplementary Figures 6A,B) were consistent with the identification of m/z 747.6 as
palmitoyl-oleoyl-PG (POPG) and m/z 788.6 as stearoyl-oleoyl-PS (SOPS). The negative
ion MALDI CID spectra obtained directly from the tissue (Supplementary Figures 6C,D)
were consistent with the identification of m/z 766.6 as stearoyl-arachidonoyl-PE (SAPE)
and m/z 885.6 as stearoyl-arachidonoyl-PI (SAPI).
The negative ion MALDI images reveal a unique distribution of
phosphatidylglycerol (PG), phosphatidylserine (PS), phosphatidylethanolamine (PE), and
phosphatidylinositol (PI) lipid molecular species across the lung slice (Figure 5). The
MALDI images of m/z 747.6 and 788.6 (Figures 5A-B) indicated that these molecular
species are present in the lung parenchyma (Figure 5E). Additionally, the negative ion
MALDI images of m/z 745.6, palmitoyl-linoleoyl-PG (PLPG), (Supplementary Figure
7A) and m/z 810.6, stearoyl-arachidonoyl-PS (SAPS), (Supplementary Figure 7B)
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indicated that these molecular species had a distribution very similar to both POPG and
SOPS.
Additionally, the MALDI images of m/z 766.6 and 885.6 (Figures 5C-D)
indicated that these phospholipids were particularly abundant at the edges of the airways
observed in the modified Giemsa stain (Figure 5E). These molecular species were also
present in the parenchyma, although with a much lower signal intensity. Similar
MALDI images were observed in negative ion mode for m/z 722.6, 1-O-hexadecenyl-
arachidonoyl-PE (HAPE), (Supplementary Figure 7C) and m/z 857.6, palmitoyl-
arachidonoyl-PI (PAPI), (Supplementary Figure 7D). These negative ion MALDI images
of arachidonate-containing phospholipids in the lung were similar to the PUFA-
containing PC lipids with a signal highly enriched at the edges of the airways.
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Discussion
Most tissues that have been examined by MALDI IMS are non-porous and do not
require inflation of the tissue or support by an embedding compound in order to obtain
high quality slices on the cryostat (27). One of the challenges in preparing lung tissue for
MALDI IMS is the spongy nature of this organ. Frozen, non-inflated lung tissue was
very difficult to section on the cryostat and the resulting sections had compromised
morphology (e.g. compressed alveoli) and it became clear that inflation of the lung was
necessary in order to maintain the lung architecture. However, the two most common
lung preparation methods used for pulmonary histological studies, agarose inflation with
FFPE or OCT embedding, did not provide useful MALDI images (Supplementary Figure
1). It is thought that the lack of phospholipid signal from a FFPE lung (Figure 1B) is most
likely due to the ethanol dehydration step of the FFPE procedure, which would cause the
phospholipids to be rinsed away. Additionally, the poor quality of the positive ion
MALDI image of the agarose inflated, OCT embedded lung (Supplementary Figures 1D-
F) was in part due to the presence of OCT, which has been shown to alter the ions
observed in mass spectra (22), largely because the benzalkonium ion present as a
preservative readily forms adduct ions with phospholipids and otherwise suppresses ion
formation of species of interest. In order to achieve high quality MALDI images of
phospholipids in lung, it was necessary to develop a new inflation and cryoembedding
media. The use of the modified OCT cryoembedding agent, composed of 10% PVA 6-98
and 8% PPG 2000, resulted in MALDI mass spectra of phospholipids directly from the
lung tissue (Figures 1D and 4B) that were quite comparable to the ESI mass spectrum of
homogenized lung (Figures 1A and 4A). The mOCT was essential for obtaining MALDI
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images that readily indicated the distribution of specific phospholipids in the lung
(Figures 2 and 5).
Lung surfactant, made by type II alveolar cells, is a complex mixture composed
primarily of phospholipids (80-90%) with PG and PC lipids accounting for 10% and
85%, respectively, of the total phospholipids in pulmonary surfactant (28). The majority
of PC in the pulmonary surfactant is present as DPPC (58%), PPoPC (13%), POPC
(7.2%), and PMPC (4.7%) (29). Additionally, the PG lipids found in surfactant of most
mammals are present as PPoPG, POPG, and PLPG (30,31). The MALDI images of these
PG and PC surfactant lipids listed above (Figures 2A-B and 5A and Supplementary
Figures 4A-B and 7A) indicated a relatively uniform intensity of these molecular species
in the lung parenchyma. The distribution of the surfactant phospholipids in the MALDI
images is quite characteristic of surfactant because of its prolific presence in the alveolar
region, which is where the surfactant is synthesized, stored, and secreted.
The MALDI images of PUFA-containing PC, PE, and PI lipids (Figures 2C-D
and 5C-D and Supplementary Figures 4C and 7C-D) indicated that these particular
molecular species are very intense at the edges of many airways. These PUFA-
containing PC, PE, and PI lipids have been reported to be in very low abundance in
pulmonary surfactant (31) and it is reasonable to conclude that the observed signal for
PUFA-containing PC, PE, and PI lipids originated from pulmonary cellular membranes.
From the unique location of the highest concentration of these phospholipids, it would
appear that the epithelial lining of airways would be the most likely cellular origin,
however the spatial resolution of MALDI IMS (~50 µm) was not adequate to ascertain
the exact cellular source of the PUFA-containing PC, PE, and PI lipid signals in the
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MALDI images of lung tissue. The phospholipid composition of the many pulmonary
cell types has not been extensively studied, but limited studies on the phospholipid
content of tracheal epithelial cells (32) and human fetal type II alveolar epithelial cells
(33) have indicated that the PUFA-containing PC, PE, and PI lipids observed in the
MALDI images are present in these cells.
The discovery that arachidonic acid containing lipids are localized at highest
concentrations in specific regions of the lung is valuable because these lipids are the
precursors to leukotriene and prostaglandin production. Incorporation of arachidonic
acid into phospholipids occurs through the Lands cycle (34) and is likely mediated by the
lysophospholipid acyl transferases, MBOAT5 and MBOAT7 (35). It is possible that the
arachidonate-containing PI, PC, and PE observed at the edges of the airways by MALDI
IMS could be a source of the arachidonic acid that is the substrate for 5-lipoxygenase or
cyclooxygenases and the eventual production of lipid mediators that affect airway
conductance relevant to both asthma (36) and chronic obstructive pulmonary disease
(37). In a similar fashion docosahexaenoate-containing phospholipids at this unique site
might provide the precursor pool of the pro-resolution mediators from subsequent
metabolism of this fatty acid (7).
For the first time, it was found that PUFA-containing phospholipids are present at
high concentrations in the airways of pulmonary tissue in the mouse. Little is known
about how such unique distributions of arachidonate- and docosahexaenoate-containing
phospholipids change during alteration of biochemistry within the lung during lung
disease or after exposure to environmental toxicants, but the MALDI IMS approach
presented here makes it possible to investigate these questions.
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Acknowledgements
This work was supported, in part, by grants from the Heart, Lung, and Blood
Institute (HL25785) and the LipidMAPS Large Scale Collaborative grant from General
Medical Sciences Institute (GM069338) of the National Institutes of Health.
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Figure Legends
Figure 1. Positive ion electrospray and MALDI mass spectrometric analysis of lung. (A)
Positive ion electrospray mass spectrum of the Bligh Dyer extract of a homogenized
mouse lung. (B) Total positive ion MALDI mass spectrum of an agarose inflated, FFPE
lung. (C) Total positive ion MALDI mass spectrum of an agarose inflated, OCT
embedded lung. (D) Total positive ion MALDI mass spectrum directly off of a mOCT
inflated and embedded lung.
Figure 2. The localization of phosphatidylcholine and sphingomyelin lipids in lung
tissue. Extracted positive ion MALDI images of (A) DPPC (m/z 734.6), (B) POPC (m/z
760.6), (C) PAPC (m/z 782.6), (D) PDoPC (m/z 806.6), and (E) SM(d18:1/16:0)+Na
(m/z 725.6) from a mOCT inflated and embedded mouse lung section. (F) Modified
Giemsa stain of the same lung after MALDI imaging.
Figure 3. The anatomical structures in the lung were unequivocally identified by dual
immunofluorescence and compared to the MALDI images. (A) Enlargement of the
boxed part of the modified Giemsa stain of a section of a mOCT inflated and embedded
mouse lung in Figure 2F. Positive ion MALDI image of PAPC (m/z 782.6) (B) and
SM(d18:1/16:0)+Na (m/z 725.6) (C). (D) Merged positive ion MALDI image of PAPC
(green) and SM(d18:1/16:0)+Na (red). (E-H) Increasingly magnified images of an
adjacent tissue section illustrating the localization of airways by acetylated tubulin (ACT,
green), blood vessels by thrombomodulin (TM, red) and cell nuclei by DAPI (blue).
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Figure 4. Negative ion electrospray and MALDI mass spectrometric analysis of lung. (A)
Negative ion electrospray mass spectrum of the Bligh Dyer extract of a homogenized
mouse lung. (B) Total negative ion MALDI mass spectrum directly off of a mOCT
inflated and embedded lung.
Figure 5. The localization of phosphatidylglycerol, phosphatidylserine,
phosphatidylethanolamine, and phosphatidylinositol lipids in lung tissue. Extracted
negative ion MALDI images of (A) POPG (m/z 747.6), (B) SOPS (m/z 788.6), (C) SAPE
(m/z 766.6), and (D) SAPI (m/z 885.6) from a section a mouse lung. (E) Modified
Giemsa stain of the same lung after MALDI imaging.
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750 800 700
10
sign
al
m/z
724.2
800.2
850
700 800 750 850 m/z
1200
600
sign
al
734.6
756.6
782.6
725.
6
706.
6
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810.6
760.
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700 750 800 850 m/z, Da
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734.6
760.6 810.6
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Figure 1
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3224
1612
A
m/z 734.6 DPPC
608
304
B
m/z 760.6 POPC
1110
555
C
m/z 782.6 PAPC
500
250
E
m/z 725.6 SM(d18:1/16:0)+Na
F
1 mm
Figure 2
394
197
D
m/z 806.6 PDoPC
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A m/z 782.6 PAPC
B
PAPC SM(d18:1/16:0)+Na
Dm/z 725.6 SM(d18:1/16:0)+Na
C
E F airways
G H 0.2 mm 0.1 mm
0.05 mm 0.05 mm
DAPI ACT TM
Figure 3
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Figure 4
700 800 750 850 m/z
900
120
80
sign
al
40
747.
6
766.
6
722.6 810.6
834.6 853.6
885.6
788.6
700 750 800 850 900 m/z
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gnal
745.6 747.6 885.6
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B
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Figure 5
70
35
120
60
110
55
190
95
A m/z 747.6 POPG
B m/z 788.6 SOPS
C m/z 766.6 SAPE
D m/z 885.6 SAPI
E
1 mm
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